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import os | |
import cv2 | |
import sys | |
import torch | |
import random | |
import psutil | |
import shutil | |
import numpy as np | |
import gradio as gr | |
from PIL import Image | |
from pathlib import Path | |
import poselib | |
from itertools import combinations | |
from typing import Callable, Dict, Any, Optional, Tuple, List, Union | |
from hloc import matchers, extractors, logger | |
from hloc.utils.base_model import dynamic_load | |
from hloc import match_dense, match_features, extract_features | |
from .viz import ( | |
fig2im, | |
plot_images, | |
display_matches, | |
display_keypoints, | |
plot_color_line_matches, | |
) | |
import time | |
import matplotlib.pyplot as plt | |
import warnings | |
import tempfile | |
import pickle | |
warnings.simplefilter("ignore") | |
device = "cuda" if torch.cuda.is_available() else "cpu" | |
ROOT = Path(__file__).parent.parent | |
# some default values | |
DEFAULT_SETTING_THRESHOLD = 0.1 | |
DEFAULT_SETTING_MAX_FEATURES = 2000 | |
DEFAULT_DEFAULT_KEYPOINT_THRESHOLD = 0.01 | |
DEFAULT_ENABLE_RANSAC = True | |
DEFAULT_RANSAC_METHOD = "CV2_USAC_MAGSAC" | |
DEFAULT_RANSAC_REPROJ_THRESHOLD = 8 | |
DEFAULT_RANSAC_CONFIDENCE = 0.999 | |
DEFAULT_RANSAC_MAX_ITER = 10000 | |
DEFAULT_MIN_NUM_MATCHES = 4 | |
DEFAULT_MATCHING_THRESHOLD = 0.2 | |
DEFAULT_SETTING_GEOMETRY = "Homography" | |
GRADIO_VERSION = gr.__version__.split(".")[0] | |
MATCHER_ZOO = None | |
class ModelCache: | |
def __init__(self, max_memory_size: int = 8): | |
self.max_memory_size = max_memory_size | |
self.current_memory_size = 0 | |
self.model_dict = {} | |
self.model_timestamps = [] | |
def cache_model(self, model_key, model_loader_func, model_conf): | |
if model_key in self.model_dict: | |
self.model_timestamps.remove(model_key) | |
self.model_timestamps.append(model_key) | |
logger.info(f"Load cached {model_key}") | |
return self.model_dict[model_key] | |
model = self._load_model_from_disk(model_loader_func, model_conf) | |
while self._calculate_model_memory() > self.max_memory_size: | |
if len(self.model_timestamps) == 0: | |
logger.warn( | |
"RAM: {}GB, MAX RAM: {}GB".format( | |
self._calculate_model_memory(), self.max_memory_size | |
) | |
) | |
break | |
oldest_model_key = self.model_timestamps.pop(0) | |
self.current_memory_size = self._calculate_model_memory() | |
logger.info(f"Del cached {oldest_model_key}") | |
del self.model_dict[oldest_model_key] | |
self.model_dict[model_key] = model | |
self.model_timestamps.append(model_key) | |
self.print_memory_usage() | |
logger.info(f"Total cached {list(self.model_dict.keys())}") | |
return model | |
def _load_model_from_disk(self, model_loader_func, model_conf): | |
return model_loader_func(model_conf) | |
def _calculate_model_memory(self, verbose=False): | |
host_colocation = int(os.environ.get("HOST_COLOCATION", "1")) | |
vm = psutil.virtual_memory() | |
du = shutil.disk_usage(".") | |
vm_ratio = host_colocation * vm.used / vm.total | |
if verbose: | |
logger.info( | |
f"RAM: {vm.used / 1e9:.1f}/{vm.total / host_colocation / 1e9:.1f}GB" | |
) | |
# logger.info( | |
# f"DISK: {du.used / 1e9:.1f}/{du.total / host_colocation / 1e9:.1f}GB" | |
# ) | |
return vm.used / 1e9 | |
def print_memory_usage(self): | |
self._calculate_model_memory(verbose=True) | |
model_cache = ModelCache() | |
def load_config(config_name: str) -> Dict[str, Any]: | |
""" | |
Load a YAML configuration file. | |
Args: | |
config_name: The path to the YAML configuration file. | |
Returns: | |
The configuration dictionary, with string keys and arbitrary values. | |
""" | |
import yaml | |
with open(config_name, "r") as stream: | |
try: | |
config: Dict[str, Any] = yaml.safe_load(stream) | |
except yaml.YAMLError as exc: | |
logger.error(exc) | |
return config | |
def get_matcher_zoo( | |
matcher_zoo: Dict[str, Dict[str, Union[str, bool]]] | |
) -> Dict[str, Dict[str, Union[Callable, bool]]]: | |
""" | |
Restore matcher configurations from a dictionary. | |
Args: | |
matcher_zoo: A dictionary with the matcher configurations, | |
where the configuration is a dictionary as loaded from a YAML file. | |
Returns: | |
A dictionary with the matcher configurations, where the configuration is | |
a function or a function instead of a string. | |
""" | |
matcher_zoo_restored = {} | |
for k, v in matcher_zoo.items(): | |
matcher_zoo_restored[k] = parse_match_config(v) | |
return matcher_zoo_restored | |
def parse_match_config(conf): | |
if conf["dense"]: | |
return { | |
"matcher": match_dense.confs.get(conf["matcher"]), | |
"dense": True, | |
} | |
else: | |
return { | |
"feature": extract_features.confs.get(conf["feature"]), | |
"matcher": match_features.confs.get(conf["matcher"]), | |
"dense": False, | |
} | |
def get_model(match_conf: Dict[str, Any]): | |
""" | |
Load a matcher model from the provided configuration. | |
Args: | |
match_conf: A dictionary containing the model configuration. | |
Returns: | |
A matcher model instance. | |
""" | |
Model = dynamic_load(matchers, match_conf["model"]["name"]) | |
model = Model(match_conf["model"]).eval().to(device) | |
return model | |
def get_feature_model(conf: Dict[str, Dict[str, Any]]): | |
""" | |
Load a feature extraction model from the provided configuration. | |
Args: | |
conf: A dictionary containing the model configuration. | |
Returns: | |
A feature extraction model instance. | |
""" | |
Model = dynamic_load(extractors, conf["model"]["name"]) | |
model = Model(conf["model"]).eval().to(device) | |
return model | |
def gen_examples(): | |
random.seed(1) | |
example_matchers = [ | |
"disk+lightglue", | |
"xfeat(sparse)", | |
"dedode", | |
"loftr", | |
"disk", | |
"RoMa", | |
"d2net", | |
"aspanformer", | |
"topicfm", | |
"superpoint+superglue", | |
"superpoint+lightglue", | |
"superpoint+mnn", | |
"disk", | |
] | |
def distribute_elements(A, B): | |
new_B = np.array(B, copy=True).flatten() | |
np.random.shuffle(new_B) | |
new_B = np.resize(new_B, len(A)) | |
np.random.shuffle(new_B) | |
return new_B.tolist() | |
# normal examples | |
def gen_images_pairs(count: int = 5): | |
path = str(ROOT / "datasets/sacre_coeur/mapping") | |
imgs_list = [ | |
os.path.join(path, file) | |
for file in os.listdir(path) | |
if file.lower().endswith((".jpg", ".jpeg", ".png")) | |
] | |
pairs = list(combinations(imgs_list, 2)) | |
if len(pairs) < count: | |
count = len(pairs) | |
selected = random.sample(range(len(pairs)), count) | |
return [pairs[i] for i in selected] | |
# rotated examples | |
def gen_rot_image_pairs(count: int = 10): | |
path = ROOT / "datasets/sacre_coeur/mapping" | |
path_rot = ROOT / "datasets/sacre_coeur/mapping_rot" | |
rot_list = [45, 180, 90, 225, 270] | |
pairs = [] | |
for file in os.listdir(path): | |
if file.lower().endswith((".jpg", ".jpeg", ".png")): | |
for rot in rot_list: | |
file_rot = "{}_rot{}.jpg".format(Path(file).stem, rot) | |
if (path_rot / file_rot).exists(): | |
pairs.append( | |
[ | |
path / file, | |
path_rot / file_rot, | |
] | |
) | |
if len(pairs) < count: | |
count = len(pairs) | |
selected = random.sample(range(len(pairs)), count) | |
return [pairs[i] for i in selected] | |
# extramely hard examples | |
def gen_image_pairs_wxbs(count: int = None): | |
prefix = "datasets/wxbs_benchmark/.WxBS/v1.1" | |
wxbs_path = ROOT / prefix | |
pairs = [] | |
for catg in os.listdir(wxbs_path): | |
catg_path = wxbs_path / catg | |
if not catg_path.is_dir(): | |
continue | |
for scene in os.listdir(catg_path): | |
scene_path = catg_path / scene | |
if not scene_path.is_dir(): | |
continue | |
img1_path = scene_path / "01.png" | |
img2_path = scene_path / "02.png" | |
if img1_path.exists() and img2_path.exists(): | |
pairs.append([str(img1_path), str(img2_path)]) | |
return pairs | |
# image pair path | |
pairs = gen_images_pairs() | |
pairs += gen_rot_image_pairs() | |
pairs += gen_image_pairs_wxbs() | |
match_setting_threshold = DEFAULT_SETTING_THRESHOLD | |
match_setting_max_features = DEFAULT_SETTING_MAX_FEATURES | |
detect_keypoints_threshold = DEFAULT_DEFAULT_KEYPOINT_THRESHOLD | |
ransac_method = DEFAULT_RANSAC_METHOD | |
ransac_reproj_threshold = DEFAULT_RANSAC_REPROJ_THRESHOLD | |
ransac_confidence = DEFAULT_RANSAC_CONFIDENCE | |
ransac_max_iter = DEFAULT_RANSAC_MAX_ITER | |
input_lists = [] | |
dist_examples = distribute_elements(pairs, example_matchers) | |
for pair, mt in zip(pairs, dist_examples): | |
input_lists.append( | |
[ | |
pair[0], | |
pair[1], | |
match_setting_threshold, | |
match_setting_max_features, | |
detect_keypoints_threshold, | |
mt, | |
# enable_ransac, | |
ransac_method, | |
ransac_reproj_threshold, | |
ransac_confidence, | |
ransac_max_iter, | |
] | |
) | |
return input_lists | |
def set_null_pred(feature_type: str, pred: dict): | |
if feature_type == "KEYPOINT": | |
pred["mmkeypoints0_orig"] = np.array([]) | |
pred["mmkeypoints1_orig"] = np.array([]) | |
pred["mmconf"] = np.array([]) | |
elif feature_type == "LINE": | |
pred["mline_keypoints0_orig"] = np.array([]) | |
pred["mline_keypoints1_orig"] = np.array([]) | |
pred["H"] = None | |
pred["geom_info"] = {} | |
return pred | |
def _filter_matches_opencv( | |
kp0: np.ndarray, | |
kp1: np.ndarray, | |
method: int = cv2.RANSAC, | |
reproj_threshold: float = 3.0, | |
confidence: float = 0.99, | |
max_iter: int = 2000, | |
geometry_type: str = "Homography", | |
) -> Tuple[np.ndarray, np.ndarray]: | |
""" | |
Filters matches between two sets of keypoints using OpenCV's findHomography. | |
Args: | |
kp0 (np.ndarray): Array of keypoints from the first image. | |
kp1 (np.ndarray): Array of keypoints from the second image. | |
method (int, optional): RANSAC method. Defaults to "cv2.RANSAC". | |
reproj_threshold (float, optional): RANSAC reprojection threshold. Defaults to 3.0. | |
confidence (float, optional): RANSAC confidence. Defaults to 0.99. | |
max_iter (int, optional): RANSAC maximum iterations. Defaults to 2000. | |
geometry_type (str, optional): Type of geometry. Defaults to "Homography". | |
Returns: | |
Tuple[np.ndarray, np.ndarray]: Homography matrix and mask. | |
""" | |
if geometry_type == "Homography": | |
M, mask = cv2.findHomography( | |
kp0, | |
kp1, | |
method=method, | |
ransacReprojThreshold=reproj_threshold, | |
confidence=confidence, | |
maxIters=max_iter, | |
) | |
elif geometry_type == "Fundamental": | |
M, mask = cv2.findFundamentalMat( | |
kp0, | |
kp1, | |
method=method, | |
ransacReprojThreshold=reproj_threshold, | |
confidence=confidence, | |
maxIters=max_iter, | |
) | |
mask = np.array(mask.ravel().astype("bool"), dtype="bool") | |
return M, mask | |
def _filter_matches_poselib( | |
kp0: np.ndarray, | |
kp1: np.ndarray, | |
method: int = None, # not used | |
reproj_threshold: float = 3, | |
confidence: float = 0.99, | |
max_iter: int = 2000, | |
geometry_type: str = "Homography", | |
) -> dict: | |
""" | |
Filters matches between two sets of keypoints using the poselib library. | |
Args: | |
kp0 (np.ndarray): Array of keypoints from the first image. | |
kp1 (np.ndarray): Array of keypoints from the second image. | |
method (str, optional): RANSAC method. Defaults to "RANSAC". | |
reproj_threshold (float, optional): RANSAC reprojection threshold. Defaults to 3. | |
confidence (float, optional): RANSAC confidence. Defaults to 0.99. | |
max_iter (int, optional): RANSAC maximum iterations. Defaults to 2000. | |
geometry_type (str, optional): Type of geometry. Defaults to "Homography". | |
Returns: | |
dict: Information about the homography estimation. | |
""" | |
ransac_options = { | |
"max_iterations": max_iter, | |
# "min_iterations": min_iter, | |
"success_prob": confidence, | |
"max_reproj_error": reproj_threshold, | |
# "progressive_sampling": args.sampler.lower() == 'prosac' | |
} | |
if geometry_type == "Homography": | |
M, info = poselib.estimate_homography(kp0, kp1, ransac_options) | |
elif geometry_type == "Fundamental": | |
M, info = poselib.estimate_fundamental(kp0, kp1, ransac_options) | |
else: | |
raise notImplementedError("Not Implemented") | |
return M, np.array(info["inliers"]) | |
def proc_ransac_matches( | |
mkpts0: np.ndarray, | |
mkpts1: np.ndarray, | |
ransac_method: str = DEFAULT_RANSAC_METHOD, | |
ransac_reproj_threshold: float = 3.0, | |
ransac_confidence: float = 0.99, | |
ransac_max_iter: int = 2000, | |
geometry_type: str = "Homography", | |
): | |
if ransac_method.startswith("CV2"): | |
logger.info( | |
f"ransac_method: {ransac_method}, geometry_type: {geometry_type}" | |
) | |
return _filter_matches_opencv( | |
mkpts0, | |
mkpts1, | |
ransac_zoo[ransac_method], | |
ransac_reproj_threshold, | |
ransac_confidence, | |
ransac_max_iter, | |
geometry_type, | |
) | |
elif ransac_method.startswith("POSELIB"): | |
logger.info( | |
f"ransac_method: {ransac_method}, geometry_type: {geometry_type}" | |
) | |
return _filter_matches_poselib( | |
mkpts0, | |
mkpts1, | |
None, | |
ransac_reproj_threshold, | |
ransac_confidence, | |
ransac_max_iter, | |
geometry_type, | |
) | |
else: | |
raise notImplementedError("Not Implemented") | |
def filter_matches( | |
pred: Dict[str, Any], | |
ransac_method: str = DEFAULT_RANSAC_METHOD, | |
ransac_reproj_threshold: float = DEFAULT_RANSAC_REPROJ_THRESHOLD, | |
ransac_confidence: float = DEFAULT_RANSAC_CONFIDENCE, | |
ransac_max_iter: int = DEFAULT_RANSAC_MAX_ITER, | |
ransac_estimator: str = None, | |
): | |
""" | |
Filter matches using RANSAC. If keypoints are available, filter by keypoints. | |
If lines are available, filter by lines. If both keypoints and lines are | |
available, filter by keypoints. | |
Args: | |
pred (Dict[str, Any]): dict of matches, including original keypoints. | |
ransac_method (str, optional): RANSAC method. Defaults to DEFAULT_RANSAC_METHOD. | |
ransac_reproj_threshold (float, optional): RANSAC reprojection threshold. Defaults to DEFAULT_RANSAC_REPROJ_THRESHOLD. | |
ransac_confidence (float, optional): RANSAC confidence. Defaults to DEFAULT_RANSAC_CONFIDENCE. | |
ransac_max_iter (int, optional): RANSAC maximum iterations. Defaults to DEFAULT_RANSAC_MAX_ITER. | |
Returns: | |
Dict[str, Any]: filtered matches. | |
""" | |
mkpts0: Optional[np.ndarray] = None | |
mkpts1: Optional[np.ndarray] = None | |
feature_type: Optional[str] = None | |
if "mkeypoints0_orig" in pred.keys() and "mkeypoints1_orig" in pred.keys(): | |
mkpts0 = pred["mkeypoints0_orig"] | |
mkpts1 = pred["mkeypoints1_orig"] | |
feature_type = "KEYPOINT" | |
elif ( | |
"line_keypoints0_orig" in pred.keys() | |
and "line_keypoints1_orig" in pred.keys() | |
): | |
mkpts0 = pred["line_keypoints0_orig"] | |
mkpts1 = pred["line_keypoints1_orig"] | |
feature_type = "LINE" | |
else: | |
return set_null_pred(feature_type, pred) | |
if mkpts0 is None or mkpts0 is None: | |
return set_null_pred(feature_type, pred) | |
if ransac_method not in ransac_zoo.keys(): | |
ransac_method = DEFAULT_RANSAC_METHOD | |
if len(mkpts0) < DEFAULT_MIN_NUM_MATCHES: | |
return set_null_pred(feature_type, pred) | |
geom_info = compute_geometry( | |
pred, | |
ransac_method=ransac_method, | |
ransac_reproj_threshold=ransac_reproj_threshold, | |
ransac_confidence=ransac_confidence, | |
ransac_max_iter=ransac_max_iter, | |
) | |
if "Homography" in geom_info.keys(): | |
mask = geom_info["mask_h"] | |
if feature_type == "KEYPOINT": | |
pred["mmkeypoints0_orig"] = mkpts0[mask] | |
pred["mmkeypoints1_orig"] = mkpts1[mask] | |
pred["mmconf"] = pred["mconf"][mask] | |
elif feature_type == "LINE": | |
pred["mline_keypoints0_orig"] = mkpts0[mask] | |
pred["mline_keypoints1_orig"] = mkpts1[mask] | |
pred["H"] = np.array(geom_info["Homography"]) | |
else: | |
set_null_pred(feature_type, pred) | |
# do not show mask | |
geom_info.pop("mask_h", None) | |
geom_info.pop("mask_f", None) | |
pred["geom_info"] = geom_info | |
return pred | |
def compute_geometry( | |
pred: Dict[str, Any], | |
ransac_method: str = DEFAULT_RANSAC_METHOD, | |
ransac_reproj_threshold: float = DEFAULT_RANSAC_REPROJ_THRESHOLD, | |
ransac_confidence: float = DEFAULT_RANSAC_CONFIDENCE, | |
ransac_max_iter: int = DEFAULT_RANSAC_MAX_ITER, | |
) -> Dict[str, List[float]]: | |
""" | |
Compute geometric information of matches, including Fundamental matrix, | |
Homography matrix, and rectification matrices (if available). | |
Args: | |
pred (Dict[str, Any]): dict of matches, including original keypoints. | |
ransac_method (str, optional): RANSAC method. Defaults to DEFAULT_RANSAC_METHOD. | |
ransac_reproj_threshold (float, optional): RANSAC reprojection threshold. Defaults to DEFAULT_RANSAC_REPROJ_THRESHOLD. | |
ransac_confidence (float, optional): RANSAC confidence. Defaults to DEFAULT_RANSAC_CONFIDENCE. | |
ransac_max_iter (int, optional): RANSAC maximum iterations. Defaults to DEFAULT_RANSAC_MAX_ITER. | |
Returns: | |
Dict[str, List[float]]: geometric information in form of a dict. | |
""" | |
mkpts0: Optional[np.ndarray] = None | |
mkpts1: Optional[np.ndarray] = None | |
if "mkeypoints0_orig" in pred.keys() and "mkeypoints1_orig" in pred.keys(): | |
mkpts0 = pred["mkeypoints0_orig"] | |
mkpts1 = pred["mkeypoints1_orig"] | |
elif ( | |
"line_keypoints0_orig" in pred.keys() | |
and "line_keypoints1_orig" in pred.keys() | |
): | |
mkpts0 = pred["line_keypoints0_orig"] | |
mkpts1 = pred["line_keypoints1_orig"] | |
if mkpts0 is not None and mkpts1 is not None: | |
if len(mkpts0) < 2 * DEFAULT_MIN_NUM_MATCHES: | |
return {} | |
geo_info: Dict[str, List[float]] = {} | |
F, mask_f = proc_ransac_matches( | |
mkpts0, | |
mkpts1, | |
ransac_method, | |
ransac_reproj_threshold, | |
ransac_confidence, | |
ransac_max_iter, | |
geometry_type="Fundamental", | |
) | |
if F is not None: | |
geo_info["Fundamental"] = F.tolist() | |
geo_info["mask_f"] = mask_f | |
H, mask_h = proc_ransac_matches( | |
mkpts1, | |
mkpts0, | |
ransac_method, | |
ransac_reproj_threshold, | |
ransac_confidence, | |
ransac_max_iter, | |
geometry_type="Homography", | |
) | |
h0, w0, _ = pred["image0_orig"].shape | |
if H is not None: | |
geo_info["Homography"] = H.tolist() | |
geo_info["mask_h"] = mask_h | |
try: | |
_, H1, H2 = cv2.stereoRectifyUncalibrated( | |
mkpts0.reshape(-1, 2), | |
mkpts1.reshape(-1, 2), | |
F, | |
imgSize=(w0, h0), | |
) | |
geo_info["H1"] = H1.tolist() | |
geo_info["H2"] = H2.tolist() | |
except cv2.error as e: | |
logger.error(f"StereoRectifyUncalibrated failed, skip!") | |
return geo_info | |
else: | |
return {} | |
def wrap_images( | |
img0: np.ndarray, | |
img1: np.ndarray, | |
geo_info: Optional[Dict[str, List[float]]], | |
geom_type: str, | |
) -> Tuple[Optional[str], Optional[Dict[str, List[float]]]]: | |
""" | |
Wraps the images based on the geometric transformation used to align them. | |
Args: | |
img0: numpy array representing the first image. | |
img1: numpy array representing the second image. | |
geo_info: dictionary containing the geometric transformation information. | |
geom_type: type of geometric transformation used to align the images. | |
Returns: | |
A tuple containing a base64 encoded image string and a dictionary with the transformation matrix. | |
""" | |
h0, w0, _ = img0.shape | |
h1, w1, _ = img1.shape | |
result_matrix: Optional[np.ndarray] = None | |
if geo_info is not None and len(geo_info) != 0: | |
rectified_image0 = img0 | |
rectified_image1 = None | |
if "Homography" not in geo_info: | |
logger.warning(f"{geom_type} not exist, maybe too less matches") | |
return None, None | |
H = np.array(geo_info["Homography"]) | |
title: List[str] = [] | |
if geom_type == "Homography": | |
rectified_image1 = cv2.warpPerspective(img1, H, (w0, h0)) | |
result_matrix = H | |
title = ["Image 0", "Image 1 - warped"] | |
elif geom_type == "Fundamental": | |
if geom_type not in geo_info: | |
logger.warning(f"{geom_type} not exist, maybe too less matches") | |
return None, None | |
else: | |
H1, H2 = np.array(geo_info["H1"]), np.array(geo_info["H2"]) | |
rectified_image0 = cv2.warpPerspective(img0, H1, (w0, h0)) | |
rectified_image1 = cv2.warpPerspective(img1, H2, (w1, h1)) | |
result_matrix = np.array(geo_info["Fundamental"]) | |
title = ["Image 0 - warped", "Image 1 - warped"] | |
else: | |
print("Error: Unknown geometry type") | |
fig = plot_images( | |
[rectified_image0.squeeze(), rectified_image1.squeeze()], | |
title, | |
dpi=300, | |
) | |
return fig2im(fig), rectified_image1 | |
else: | |
return None, None | |
def generate_warp_images( | |
input_image0: np.ndarray, | |
input_image1: np.ndarray, | |
matches_info: Dict[str, Any], | |
choice: str, | |
) -> Tuple[Optional[np.ndarray], Optional[np.ndarray]]: | |
""" | |
Changes the estimate of the geometric transformation used to align the images. | |
Args: | |
input_image0: First input image. | |
input_image1: Second input image. | |
matches_info: Dictionary containing information about the matches. | |
choice: Type of geometric transformation to use ('Homography' or 'Fundamental') or 'No' to disable. | |
Returns: | |
A tuple containing the updated images and the warpped images. | |
""" | |
if ( | |
matches_info is None | |
or len(matches_info) < 1 | |
or "geom_info" not in matches_info.keys() | |
): | |
return None, None | |
geom_info = matches_info["geom_info"] | |
wrapped_images = None | |
if choice != "No": | |
wrapped_image_pair, warped_image = wrap_images( | |
input_image0, input_image1, geom_info, choice | |
) | |
return wrapped_image_pair, warped_image | |
else: | |
return None, None | |
def send_to_match(state_cache: Dict[str, Any]): | |
""" | |
Send the state cache to the match function. | |
Args: | |
state_cache (Dict[str, Any]): Current state of the app. | |
Returns: | |
None | |
""" | |
if state_cache: | |
return ( | |
state_cache["image0_orig"], | |
state_cache["wrapped_image"], | |
) | |
else: | |
return None, None | |
def run_ransac( | |
state_cache: Dict[str, Any], | |
choice_geometry_type: str, | |
ransac_method: str = DEFAULT_RANSAC_METHOD, | |
ransac_reproj_threshold: int = DEFAULT_RANSAC_REPROJ_THRESHOLD, | |
ransac_confidence: float = DEFAULT_RANSAC_CONFIDENCE, | |
ransac_max_iter: int = DEFAULT_RANSAC_MAX_ITER, | |
) -> Tuple[Optional[np.ndarray], Optional[Dict[str, int]]]: | |
""" | |
Run RANSAC matches and return the output images and the number of matches. | |
Args: | |
state_cache (Dict[str, Any]): Current state of the app, including the matches. | |
ransac_method (str, optional): RANSAC method. Defaults to DEFAULT_RANSAC_METHOD. | |
ransac_reproj_threshold (int, optional): RANSAC reprojection threshold. Defaults to DEFAULT_RANSAC_REPROJ_THRESHOLD. | |
ransac_confidence (float, optional): RANSAC confidence. Defaults to DEFAULT_RANSAC_CONFIDENCE. | |
ransac_max_iter (int, optional): RANSAC maximum iterations. Defaults to DEFAULT_RANSAC_MAX_ITER. | |
Returns: | |
Tuple[Optional[np.ndarray], Optional[Dict[str, int]]]: Tuple containing the output images and the number of matches. | |
""" | |
if not state_cache: | |
logger.info("Run Match first before Rerun RANSAC") | |
gr.Warning("Run Match first before Rerun RANSAC") | |
return None, None | |
t1 = time.time() | |
logger.info( | |
f"Run RANSAC matches using: {ransac_method} with threshold: {ransac_reproj_threshold}" | |
) | |
logger.info( | |
f"Run RANSAC matches using: {ransac_confidence} with iter: {ransac_max_iter}" | |
) | |
# if enable_ransac: | |
filter_matches( | |
state_cache, | |
ransac_method=ransac_method, | |
ransac_reproj_threshold=ransac_reproj_threshold, | |
ransac_confidence=ransac_confidence, | |
ransac_max_iter=ransac_max_iter, | |
) | |
logger.info(f"RANSAC matches done using: {time.time()-t1:.3f}s") | |
t1 = time.time() | |
# plot images with ransac matches | |
titles = [ | |
"Image 0 - Ransac matched keypoints", | |
"Image 1 - Ransac matched keypoints", | |
] | |
output_matches_ransac, num_matches_ransac = display_matches( | |
state_cache, titles=titles, tag="KPTS_RANSAC" | |
) | |
logger.info(f"Display matches done using: {time.time()-t1:.3f}s") | |
t1 = time.time() | |
# compute warp images | |
output_wrapped, warped_image = generate_warp_images( | |
state_cache["image0_orig"], | |
state_cache["image1_orig"], | |
state_cache, | |
choice_geometry_type, | |
) | |
plt.close("all") | |
num_matches_raw = state_cache["num_matches_raw"] | |
state_cache["wrapped_image"] = warped_image | |
# tmp_state_cache = tempfile.NamedTemporaryFile(suffix='.pkl', delete=False) | |
tmp_state_cache = "output.pkl" | |
with open(tmp_state_cache, "wb") as f: | |
pickle.dump(state_cache, f) | |
logger.info(f"Dump results done!") | |
return ( | |
output_matches_ransac, | |
{ | |
"num_matches_raw": num_matches_raw, | |
"num_matches_ransac": num_matches_ransac, | |
}, | |
output_wrapped, | |
tmp_state_cache, | |
) | |
def run_matching( | |
image0: np.ndarray, | |
image1: np.ndarray, | |
match_threshold: float, | |
extract_max_keypoints: int, | |
keypoint_threshold: float, | |
key: str, | |
ransac_method: str = DEFAULT_RANSAC_METHOD, | |
ransac_reproj_threshold: int = DEFAULT_RANSAC_REPROJ_THRESHOLD, | |
ransac_confidence: float = DEFAULT_RANSAC_CONFIDENCE, | |
ransac_max_iter: int = DEFAULT_RANSAC_MAX_ITER, | |
choice_geometry_type: str = DEFAULT_SETTING_GEOMETRY, | |
matcher_zoo: Dict[str, Any] = None, | |
use_cached_model: bool = False, | |
) -> Tuple[ | |
np.ndarray, | |
np.ndarray, | |
np.ndarray, | |
Dict[str, int], | |
Dict[str, Dict[str, Any]], | |
Dict[str, Dict[str, float]], | |
np.ndarray, | |
]: | |
"""Match two images using the given parameters. | |
Args: | |
image0 (np.ndarray): RGB image 0. | |
image1 (np.ndarray): RGB image 1. | |
match_threshold (float): match threshold. | |
extract_max_keypoints (int): number of keypoints to extract. | |
keypoint_threshold (float): keypoint threshold. | |
key (str): key of the model to use. | |
ransac_method (str, optional): RANSAC method to use. | |
ransac_reproj_threshold (int, optional): RANSAC reprojection threshold. | |
ransac_confidence (float, optional): RANSAC confidence level. | |
ransac_max_iter (int, optional): RANSAC maximum number of iterations. | |
choice_geometry_type (str, optional): setting of geometry estimation. | |
Returns: | |
tuple: | |
- output_keypoints (np.ndarray): image with keypoints. | |
- output_matches_raw (np.ndarray): image with raw matches. | |
- output_matches_ransac (np.ndarray): image with RANSAC matches. | |
- num_matches (Dict[str, int]): number of raw and RANSAC matches. | |
- configs (Dict[str, Dict[str, Any]]): match and feature extraction configs. | |
- geom_info (Dict[str, Dict[str, float]]): geometry information. | |
- output_wrapped (np.ndarray): wrapped images. | |
""" | |
# image0 and image1 is RGB mode | |
if image0 is None or image1 is None: | |
logger.error( | |
"Error: No images found! Please upload two images or select an example." | |
) | |
raise gr.Error( | |
"Error: No images found! Please upload two images or select an example." | |
) | |
# init output | |
output_keypoints = None | |
output_matches_raw = None | |
output_matches_ransac = None | |
# super slow! | |
if "roma" in key.lower() and device == "cpu": | |
gr.Info( | |
f"Success! Please be patient and allow for about 2-3 minutes." | |
f" Due to CPU inference, {key} is quiet slow." | |
) | |
t0 = time.time() | |
model = matcher_zoo[key] | |
match_conf = model["matcher"] | |
# update match config | |
match_conf["model"]["match_threshold"] = match_threshold | |
match_conf["model"]["max_keypoints"] = extract_max_keypoints | |
cache_key = "{}_{}".format(key, match_conf["model"]["name"]) | |
if use_cached_model: | |
# because of the model cache, we need to update the config | |
matcher = model_cache.cache_model(cache_key, get_model, match_conf) | |
matcher.conf["max_keypoints"] = extract_max_keypoints | |
matcher.conf["match_threshold"] = match_threshold | |
logger.info(f"Loaded cached model {cache_key}") | |
else: | |
matcher = get_model(match_conf) | |
logger.info(f"Loading model using: {time.time()-t0:.3f}s") | |
t1 = time.time() | |
if model["dense"]: | |
pred = match_dense.match_images( | |
matcher, image0, image1, match_conf["preprocessing"], device=device | |
) | |
del matcher | |
extract_conf = None | |
else: | |
extract_conf = model["feature"] | |
# update extract config | |
extract_conf["model"]["max_keypoints"] = extract_max_keypoints | |
extract_conf["model"]["keypoint_threshold"] = keypoint_threshold | |
cache_key = "{}_{}".format(key, extract_conf["model"]["name"]) | |
if use_cached_model: | |
extractor = model_cache.cache_model( | |
cache_key, get_feature_model, extract_conf | |
) | |
# because of the model cache, we need to update the config | |
extractor.conf["max_keypoints"] = extract_max_keypoints | |
extractor.conf["keypoint_threshold"] = keypoint_threshold | |
logger.info(f"Loaded cached model {cache_key}") | |
else: | |
extractor = get_feature_model(extract_conf) | |
pred0 = extract_features.extract( | |
extractor, image0, extract_conf["preprocessing"] | |
) | |
pred1 = extract_features.extract( | |
extractor, image1, extract_conf["preprocessing"] | |
) | |
pred = match_features.match_images(matcher, pred0, pred1) | |
del extractor | |
gr.Info( | |
f"Matching images done using: {time.time()-t1:.3f}s", | |
) | |
logger.info(f"Matching images done using: {time.time()-t1:.3f}s") | |
t1 = time.time() | |
# plot images with keypoints | |
titles = [ | |
"Image 0 - Keypoints", | |
"Image 1 - Keypoints", | |
] | |
output_keypoints = display_keypoints(pred, titles=titles) | |
# plot images with raw matches | |
titles = [ | |
"Image 0 - Raw matched keypoints", | |
"Image 1 - Raw matched keypoints", | |
] | |
output_matches_raw, num_matches_raw = display_matches(pred, titles=titles) | |
# if enable_ransac: | |
filter_matches( | |
pred, | |
ransac_method=ransac_method, | |
ransac_reproj_threshold=ransac_reproj_threshold, | |
ransac_confidence=ransac_confidence, | |
ransac_max_iter=ransac_max_iter, | |
) | |
# gr.Info(f"RANSAC matches done using: {time.time()-t1:.3f}s") | |
logger.info(f"RANSAC matches done using: {time.time()-t1:.3f}s") | |
t1 = time.time() | |
# plot images with ransac matches | |
titles = [ | |
"Image 0 - Ransac matched keypoints", | |
"Image 1 - Ransac matched keypoints", | |
] | |
output_matches_ransac, num_matches_ransac = display_matches( | |
pred, titles=titles, tag="KPTS_RANSAC" | |
) | |
# gr.Info(f"Display matches done using: {time.time()-t1:.3f}s") | |
logger.info(f"Display matches done using: {time.time()-t1:.3f}s") | |
t1 = time.time() | |
# plot wrapped images | |
output_wrapped, warped_image = generate_warp_images( | |
pred["image0_orig"], | |
pred["image1_orig"], | |
pred, | |
choice_geometry_type, | |
) | |
plt.close("all") | |
# gr.Info(f"In summary, total time: {time.time()-t0:.3f}s") | |
logger.info(f"TOTAL time: {time.time()-t0:.3f}s") | |
state_cache = pred | |
state_cache["num_matches_raw"] = num_matches_raw | |
state_cache["num_matches_ransac"] = num_matches_ransac | |
state_cache["wrapped_image"] = warped_image | |
# tmp_state_cache = tempfile.NamedTemporaryFile(suffix='.pkl', delete=False) | |
tmp_state_cache = "output.pkl" | |
with open(tmp_state_cache, "wb") as f: | |
pickle.dump(state_cache, f) | |
logger.info(f"Dump results done!") | |
return ( | |
output_keypoints, | |
output_matches_raw, | |
output_matches_ransac, | |
{ | |
"num_raw_matches": num_matches_raw, | |
"num_ransac_matches": num_matches_ransac, | |
}, | |
{ | |
"match_conf": match_conf, | |
"extractor_conf": extract_conf, | |
}, | |
{ | |
"geom_info": pred.get("geom_info", {}), | |
}, | |
output_wrapped, | |
state_cache, | |
tmp_state_cache, | |
) | |
# @ref: https://docs.opencv.org/4.x/d0/d74/md__build_4_x-contrib_docs-lin64_opencv_doc_tutorials_calib3d_usac.html | |
# AND: https://opencv.org/blog/2021/06/09/evaluating-opencvs-new-ransacs | |
ransac_zoo = { | |
"POSELIB": "LO-RANSAC", | |
"CV2_RANSAC": cv2.RANSAC, | |
"CV2_USAC_MAGSAC": cv2.USAC_MAGSAC, | |
"CV2_USAC_DEFAULT": cv2.USAC_DEFAULT, | |
"CV2_USAC_FM_8PTS": cv2.USAC_FM_8PTS, | |
"CV2_USAC_PROSAC": cv2.USAC_PROSAC, | |
"CV2_USAC_FAST": cv2.USAC_FAST, | |
"CV2_USAC_ACCURATE": cv2.USAC_ACCURATE, | |
"CV2_USAC_PARALLEL": cv2.USAC_PARALLEL, | |
} | |
def rotate_image(input_path, degrees, output_path): | |
img = Image.open(input_path) | |
img_rotated = img.rotate(-degrees) | |
img_rotated.save(output_path) | |
def scale_image(input_path, scale_factor, output_path): | |
img = Image.open(input_path) | |
width, height = img.size | |
new_width = int(width * scale_factor) | |
new_height = int(height * scale_factor) | |
img_resized = img.resize((new_width, new_height)) | |
img_resized.save(output_path) | |